KR20190033446A - Method of operating a sewing machine and sewing machine adapted to carry out the method - Google Patents

Abstract

In operation of a sewing machine, at least one seam is sewn into one fabric piece. At the same time, a supply unit of a fabric piece is driven in a fabric supply direction (2) by a fabric supply driving mechanism (8). While the seam is being sewn, a needle supply unit (18) of the sewing machine (3) is operated in such a manner that needles (4, 5) supply the fabric piece in an opposite direction to the fabric supply direction (2), while each stitch is made. As a result, a method of operation and a sewing machine operating with such an operating method are obtained to enable an enhanced seam pattern to be produced.

Description

TECHNICAL FIELD [0001] The present invention relates to a method of operating a sewing machine and a sewing machine adapted to perform such a method,

The present invention relates to a method of operating a sewing machine. The invention further relates to a sewing machine adapted to carry out said method.

Methods of operation for sewing machines are known from EP 3 088 589 A1 and DE 100 22 237 B4. Document DE 10 2011 100 103 A1 describes a sewing machine having a needle transport unit for changing the step length. German Patent No. 1 485 148 describes a sewing machine with a needle feeder, wherein a corresponding feeding tool is provided to add the additional layer of sleeve fabric necessary for inserting the sleeve. Document DE 34 11 217 A1 describes a double-chain stitch sewing machine having a shuttle drive mechanism which is operable to set the absolute amount of swing motion or fabric feed of a sewing needle. Document DE 10 2007 004 549 A1 describes a feed adjusting device for a sewing machine. German Patent No. 868 832 describes a feeding device for a sewing machine. Document DE 33 42 391 C1 describes a sewing machine having a needle feed unit and a bottom feed mechanism.

It is an object of the present invention to further develop a sewing machine of the type designated in the outset in such a way that the seam pattern is improved.

This object is achieved by a method of operation of a sewing machine in accordance with the invention, which method comprises sewing at least one seam within a piece of fabric while simultaneously delivering the fabric piece in a fabric supply direction using a fabric supply driving mechanism And a step of operating the needle feeding unit of the sewing machine while the seam is being sewn in such a manner that the needle feeds the fabric piece in the opposite direction to the fabric feeding direction while each stitch is being produced.

It has surprisingly been found that the seam pattern is improved according to the fabric quality and fabric thickness and according to the sewing needle parameters if the needle feeding unit provided for feeding the fabric piece is operated in the opposite direction to the fabric feeding direction of the further fabric feeding drive mechanism . On the one hand, the "opposite motion" of these needle feed units and, on the other hand, its fabric feed drive mechanism may be expected to produce a bad seam pattern, but the seam pattern is in fact the type of fabric and sewing needle And is reproducibly improved by this opposite operation.

The adjustable topological relationship of the fabric feed drive mechanism to the needle feed unit allows fine adjustment of the reverse operation between the needle feed unit and the periodic operation sequence of the fabric feed drive mechanism that can be used to optimize the seam pattern. On the one hand, one cycle of the individual operation sequence of the fabric supply drive mechanism, on the other hand, one cycle of the scale supply unit may coincide with the cycle of the sewing machine forming exactly one stitch.

The advantage of fine-tuning the operating sequence is particularly applied to the adjustment of the phase relationship during the seam being sewn. For example, there may be a first phase relationship between the needle feed unit and the periodic sequence of operations of the fabric feed drive mechanism at the beginning of the seam to be sewn, while there may be a different phase relationship of this type at the end of the seam. This phase relationship adjustment enables the sewing machine to adapt to various sewing conditions during seam formation.

The length of the needle feed step in which the piece of fabric is supplied by the needle feed unit along the stitch is made - in terms of the absolute value - is smaller than the feed step length supplied by the fabric feed drive by the fabric feed drive Is proved to be particularly suitable for improving the seam pattern. The absolute relationship of the needle feed step length to the fabric feed step length may be in the range of 1/10 and 2/1. In the opposite operation, the absolute needle feed step length may also generally be greater than the fabric feed step length.

Advantages of a sewing machine adapted to carry out the method according to the invention are in accordance with what has been described above for the operating method. The sewing machine may be a single needle sewing machine or a double needle sewing machine.

A fabric supply drive configured as a fabric clamp enables independent operation of the fabric supply in the fabric supply unit for operation of the needle supply unit. Alternatively, the fabric feed drive mechanism may also be configured as a top feeder unit comprising at least one top feeder and / or as a bottom feeder unit comprising at least one bottom feeder. The fabric feed drive mechanism may feed fabric pieces to be sewn by frictional contact with fabric pieces during seam formation.

The stepper motor of the needle feed unit, which acts on the adjustment shaft to adjust the needle feed step length, allows precise setting of the needle feed step length, which can vary in small increments and is particularly substantially continuous.

The control unit adapted to define the phase relationship between the fabric supply drive mechanism and the needle supply unit enables a flexible setting of the corresponding operation between the fabric supply drive mechanism and the needle supply unit.

BRIEF DESCRIPTION OF THE DRAWINGS Exemplary embodiments of the present invention will now be described in more detail with reference to the drawings, in which:
1 is a general perspective view of the main components of a sewing unit including a double needle sewing machine;
Figs. 2 and 3 are perspective views of a needle-feeding component assembly of a sewing machine including a needle feed drive at a " forward needle feed "position and a setting component derived from the arm shaft;
Figs. 4 and 5 are similar to Figs. 2 and 3, showing the needle feed component assembly at the "back needle feed"position; And
Figs. 6 and 7 are views similar to Figs. 4 and 5, showing the appearance of the needle feed component assembly at the "neutral needle feed" position.

Fig. 1 shows a partial and schematic view of the main components of a sewing unit 1, which is used, for example, in particular for producing bags whose bag mouth is trimmed with piping. The sewing unit 1 can be used to sew additional fabric parts, such as piping, to a basic fabric part such as a pants part or soot jacket part. This sewing unit may also be used to sew flap or welt pockets.

When sewing the seam into the fabric piece, the fabric piece is simultaneously fed in a driving manner in the fabric feeding direction 2, also referred to as the sewing direction below. The sewing direction 2 extends along the X-direction of the Cartesian XYZ coordinate system included in Fig.

The sewing unit 1 has a sewing machine 3 adapted to sew a piece of fabric which is configured as a double needle sewing machine including sewing needles 4 and 5 Reference). The piping or flap folding and feeding device is located upstream of the sewing needles 4, 5 when viewed in the sewing direction 2, that is, offset in the negative X-direction. The general mode of operation of the piping supply device has been known from the prior art. More information on this can be found in the previously published documents DE 100 16 410 C1, DE 199 26 866 C1 and DE 198 45 624 C1 and their cited references.

The fabric piece is placed on the bearing plate 7 of the sewing machine 1. The bearing plate 7 defines a bearing plane parallel to the XY plane.

Outlined in dashed lines in the schematic drawing according to figure 1 only a driven fabric clamp 8, known in general from EP 3 088 589 A as a fabric feed drive mechanism, is provided on each side of the seam to be produced, Is used to squeeze the fabric piece and feed it along the sewing direction (2). The sewing machine 3 makes it possible for the additional needle supply unit of the fabric piece to be selectively activated, for example temporarily.

An operable display of the sewing unit 1, which can be configured as a touch screen, is provided to the user to select sewing programs for inputting sewing data and monitoring the sewing process. The unillustrated display is operated through the central control unit 9 shown in the schematic view of Fig.

A fabric clamp 8 comprising a clamp frame is covered by a covering hood 10.

The sewing unit (1) comprises a fabric supply transporting component adapted to supply a fabric piece to a stitch forming area with a sewing machine (3) and a mainframe receiving component adapted to emit a fabric piece from the stitch forming area 11). The main frame 11 includes a bearing plate 7. The sliding plate (12) of the sewing unit (1) is installed in the region of the bearing plate (7). The fabric pieces slide along the sliding plate 12 during feeding.

Figures 2-7 illustrate the details of the needle feed unit 18 used to create the needle feed motion, in which the needle needles 4, 5 enter the fabric strip in the sewing direction < RTI ID = 0.0 > 2 or the sewing needles 4, 5 entering the fabric piece to supply the fabric pieces in the direction opposite to the sewing direction 2 are configured to have no fabric supplying function. Figures 2 and 3 illustrate the needle supply unit 187 in the "sewing direction 2, i. E. Needle supply" setting position in the positive X-direction. Figs. 4 and 5 show a setting position in which the needle feeding unit 18 is configured to perform needle feeding movement in the opposite direction to the sewing direction 2, i.e. in the negative X-direction. Figures 6 and 7 show the needle supply unit 18 in a set position in which the sewing needles 4, 5 do not have a fabric supply function.

The needle feed drive is derived from an arm shaft 19 extending from the arm 20 of the sewing machine 3 (see Fig. 2). At the free end, the arm shaft 19 is non-rotatably connected to the manually operable hand wheel 21.

Through the eccentric 22, the arm shaft 19 acts on the needle feed adjusting gear mechanism 23. The adjusting gear mechanism 23 is configured as a tongue gear mechanism.

In the sewing operation, the arm shaft 19 is driven by a motor by a driving motor not shown in the drawing, for example, within the main frame 11 under the bearing plate 7 of the sewing machine 3, .

The adjustment gear mechanism 23 generates a swing motion of the output lever 23 of the needle supply unit 18. [ The swing angle and swing amplitude of the output lever 23 are predetermined by the corresponding gear setting of the adjusting gear mechanism 23. [ This gear setting is performed by rotating an adjusting shaft which is configured as a gear shaft 26 that interacts with the adjusting gear mechanism 23 and also runs parallel to the arm shaft 19. Thus, each angle setting of the gear shaft 26 produces different feed strokes of the needle feed unit in the sewing direction 2.

The angle setting of the gear shaft 26 can be changed by a needle feed switchover device 27 configured as an actuator in the form of a stepper motor. The stepper motor is rigidly connected to the frame of the sewing machine 3 through a frame latch 28 in a manner not shown in more detail. The motor shaft 29 of the stepper motor 27 is connected to the gear shaft 26 through the lever driving mechanism 30. [ The frame of the regulating gear mechanism 23, the output lever component 31 of the lever drive mechanism 30 and the gear shaft 26 are non-rotatably connected to each other. The swing motion of the motor shaft 29 starting from the neutral position of Figures 6 and 7 reaches the two positions of the maximum "forward needle supply" according to FIGS. 2 and 3 and the maximum "back needle supply ≪ RTI ID = 0.0 > 30.

The stepper motor 27 is in signal communication with the central control unit 9 of the sewing unit 1. This control unit 9 is used, for example, to actuate the fabric feed drive mechanism through the fabric clamp 8, the stepper motor of the needle feed switchover device 27 and the drive motor for the arm shaft 19. [

2 to 7, the needle supply unit 18 is connected to the needle supply switchover device 27 by three positions "needle supply in the sewing direction 2" (see FIG. 2/3), " Quot; needle supply "in the direction opposite to the sewing direction 2 (see FIG. 4) and the" neutral position without needle feeding function "(see FIG. 6/7).

The output lever 25 transmits the swing amplitude defined by the adjusting gear mechanism 23 to the needle bar link shaft 36. [ The swing amplitude of the needle bar link shaft 36 is thus defined by the swing amplitude of the output lever 25. The needle bar link shaft 36 also runs parallel to the arm shaft 19.

The needle bar link shaft 36 is non-rotatably connected to the needle bar link 37 for the needle bar 38 to which the two needle bars 4, 5 are fixed by the needle holder 39.

The needles 4 and 5 perform swing motion around the needle feed swing axis 40 in response to the swing amplification of the needle bar link shaft 36.

Figures 2-7 illustrate a needle lever 43 including an arm shaft crank 42 for actuating the needle bar 38 in the up and down direction and a needle lever adjusting element 44 having bearing points, As shown in FIG.

Each of the seams is sewn when the sewing machine 3 is operated while at the same time the fabric pieces are driven in the sewing direction 2, that is, in the fabric supply direction, by a fabric supply driving mechanism, . When sewing each seam, the needle feeding unit 18 is operated so that the needles 4, 5 feed the fabric pieces in reverse to the fabric feeding direction 2, while each stitch is made. Therefore, during the sewing operation, as shown in Figs. 4 and 5, defined by the operating position of the needle supply unit 18 as shown in Figs. 4 and 5 or the respective step position of the stepper motor 27, There is an intermediate position between the " needle supply "position and the neutral position as shown in FIGS.

The stepper motor 27 enables virtually continuous adjustment to be performed between the "maximum forward / backward needle feed" position as shown in FIG. 2/3 and the neutral position as shown in FIG. 6/7.

If the fabric feed drive mechanism, i. E. The fabric clamp 8, has a periodic sequence of operations while the stitches are being made, the fabric feed drive mechanism 18 may be moved to the needle feed unit 18 With an adjustable phase relationship. Thus, by activating the feed drive mechanism of the fabric clamp 8 through the control unit 9, the phase relationship can be adjusted during the formation of each seam during the formation of each stitch.

The adjustable needle feed step length through the stepper motor 27, through which the fabric piece is fed through the needle feed unit 18 during the stitching process, is controlled by the fabric clamp 8 (in terms of absolute value) May be less than the feed step length supplied by the fabric piece. In general, it is also possible that the needle feed step length - in terms of absolute value - is greater than the feed step length. The absolute step length ratio of the needle feed step length / feed step length can be in the range of 1/10 and 2/1, particularly in the range of 1/10 and 8/10, in the range of 2/10 and 7/10 Within a range of 3/10, within a range of 4/10, within a range of 5/10, or within a range of 6/10, for example. The step length of the fabric feeding step may be in the range of 2.5 mm. In opposite operation, the absolute needle feed step length may be in the range between 0.1 mm and 3.5 mm.

As an alternative to the fabric feed drive mechanism configured as a fabric clamp, the fabric feed drive mechanism may also be configured as a top feed unit and / or a bottom feed unit. A feed dog configured to provide a fabric top feed motion is known from DE 196 03 294 C1. A feed dock configured to provide a fabric floor feeding motion is known from EP 2 330 241 B1.

Adjustment of the needle feed step length can be performed in a controlled manner, for example in response to the detection of the fabric thickness. To this end, the control unit 9 can communicate with a fabric thickness sensor (not shown) and operate the stepper motor 27 when a predetermined fabric thickness is reached. Adjustment of the needle feed can also be performed in response to the measured fabric feed rate. To this end, the speed of the fabric feed during the sewing operation is monitored, for example by means of an optical sensor.

Claims (8)

A method of operating a sewing machine (3)
- sewing at least one seam in one fabric piece while simultaneously feeding said fabric piece in a fabric feeding direction (2) using a fabric feed driving mechanism (8);
While the needle feed unit 18 of the sewing machine 3 is operated while the needles 4 and 5 feed the fabric pieces in the opposite direction to the fabric feeding direction 2 while the respective stitches are being produced And sewing. The method according to claim 1,
Characterized in that the fabric supply drive mechanism (8) operates using an adjustable phase relationship for the needle supply unit (18). 3. The method of claim 2,
Wherein the phase relationship is adjusted while the seam is being sewn. The method according to claim 1,
The needle feed step length through which the fabric piece is supplied by the needle supply unit 18 while the stitch is being produced is determined by the yarn feed step length Characterized in that the fabric strip is smaller than the feeding step length supplied accordingly. A sewing machine (3) adapted to carry out the method according to claim 1. 6. The method of claim 5,
Characterized in that the fabric feed drive mechanism (8) is configured as a fabric clamp. 6. The method of claim 5,
Characterized in that the needle feed unit (18) has a stepper motor (27) acting on the adjustment shaft (26) to adjust the needle feed step length. 6. The method of claim 5,
Characterized by a control unit (9) adapted to define a phase relationship between the fabric supply drive mechanism (8) and the needle supply unit (18).

Images